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Gastric cancer carcinogenesis
and tumor progression
Ann. Ital. Chir., 2012 83: 172-176
Giovanni Corso*, Raquel Seruca**, Franco Roviello*
*Dipartimento di Patologia Umana ed Oncologia, Sezione di Chirurgia Generale e Oncologica, Università di Siena, Italia
**IPATIMUP Istitute of Molecular Pathology and Immunologo, University of Porto, Portugal
Gastric cancer carcinogenesis and tumor progression
BACKGROUND: Gastric cancer (GC) remains one of the leading causes of cancer-related deaths worldwide, even though
a decline has been observed in its incidence and the mortality rate in recent decades. Gastric carcinogenesis is a complex phenomena involving multiple epigenetic and genetic factors; several genetic, environmental and infectious agents
interact causing a cumulative effect in the early steps of gastric carcinogenesis.
MATERIALS AND METHODS: The most commonly used classifications of GC are the World Health Organization (WHO)
and the Laurén classifications which describes two main histological types, diffuse and intestinal, which have different
clinicopathological characteristics. Diffuse cancer occurs more commonly in young patients, can be multifocal, is not often
accompanied by intestinal metaplasia and can be hereditary, in which E-cadherin alteration plays a pivotal role.
Intestinal type is more frequently observed in older patients and follows multifocal atrophic gastritis. This is usually
accompanied by intestinal metaplasia and leads to cancer via dysplasia, and thus intestinal metaplasia is considered a
dependable morphological marker for GC risk. Intestinal adenocarcinoma predominates in the high-risk areas whereas
the diffuse adenocarcinoma is more common in low-risk areas.
DISCUSSION: Classically, genetic instability and Helicobater pylori (H. Pylori) infection are often identified in intestinal
GC. The great majority of GCs are sporadic and result from the cumulative effects of different environmental risk factors; smoking, alcohol consumption and dietary habits have been addressed as significant. H. Pylori infection and proinflammatory cytokine gene polymorphisms represent other features of this compound process that leads to the development
of GC. Other molecular pathway well described in GC is microsatellite instability (MSI) that related with specific clinic-pathological features.
CONCLUSION: In this review we focused on the role of H. Pylori infection, MSI and alterations of CDH1 (E-Cadherin) gene.
KEY
WORDS:
E-cadherin, Gastric tumorigenesis, Genomic instability, Helicobacter Pilory
Introduction
Gastric cancer (GC) remains one of the leading causes
of cancer-related deaths worldwide, even though a decline
has been observed in its incidence and the mortality rate
in recent decades. Gastric carcinogenesis is a complex
Correspondence to: Franco Roviello, Via Alcide De Gasperi 5, 53100
Siena, Italy (e-mail: [email protected])
172
Ann. Ital. Chir., 83, 3, 2012
phenomena involving multiple epigenetic and genetic factors; several genetic, environmental and infectious agents
interact causing a cumulative effect in the early steps of
gastric carcinogenesis.
The most commonly used classifications of GC are the
World Health Organization (WHO) and the Laurén classifications which describes two main histological types,
diffuse and intestinal, which have different clinicopathological characteristics. Diffuse cancer occurs more commonly in young patients, can be multifocal, is not often
accompanied by intestinal metaplasia and can be hereditary, in which E-cadherin alteration plays a pivotal role.
Gastric cancer carcinogenesis and tumor progression
Intestinal type is more frequently observed in older
patients and follows multifocal atrophic gastritis. This is
usually accompanied by intestinal metaplasia and leads
to cancer via dysplasia, and thus intestinal metaplasia is
considered a dependable morphological marker for GC
risk.
Intestinal adenocarcinoma predominates in the high-risk
areas whereas the diffuse adenocarcinoma is more common in low-risk areas. Classically, genetic instability and
Helicobater pylori (H. Pylori) infection are often identified in intestinal GC.
The great majority of GCs are sporadic and result from
the cumulative effects of different environmental risk factors; smoking, alcohol consumption and dietary habits
have been addressed as significant. H. Pylori infection
and proinflammatory cytokine gene polymorphisms represent other features of this compound process that leads
to the development of GC. Other molecular pathway
well described in GC is microsatellite instability (MSI)
that related with specific clinic-pathological features.
In this review we focused on the role of H. Pylori infection, MSI and alterations of CDH1 (E-Cadherin) gene.
Helicobacter Pylori infection
Several prospective studies reported a strong association
between chronic H. Pylori infection and GC; as such,
the World Health Organization’s International Agency for
Research on Cancer recognized H. Pylori as a Group 1
carcinogen for humans. Chronic gastric inflammation
and the interaction between H. Pylori and gastric epithelial cells have been suggested as potential mechanisms in
gastric carcinogenesis 1. However, only a few individuals infected by H. Pylori eventually develop GC, probably this is due to environmental factors, host-inflammatory genetic susceptibility and variation of the bacterial
strains.
H. Pylori is a Gram-negative bacterium that colonizes
the human gastric epithelium, the severity of H.
Pylori–related disease is correlated with the presence of
cag pathogenicity island (PAI) associated with production of the cagA antigen. The cagA gene, the strain-specific H. Pylori gene, is located in the right half of the
PAI, and encodes the protein cagA, which is secreted via
a type IV secretion system and translocated into gastric
epithelial cells affecting host cell physiology 2,3. Infection
with cag PAI–positive H. Pylori strains has been recognized as a marker for strains that confer increased risk
for peptic ulcer disease, gastric mucosal atrophy and GC.
The cagA gene is one of several genes of a PAI called
the cag PAI and the presence of cagA is considered to
be a marker of the presence of the cag PAI. The vacA
gene is present in all H. Pylori strains and encodes the
vacuolating cytotoxin vacA, which induces epithelial cell
injury. H. Pylori colonizes the atrophic stomach poorly,
and intestinal metaplasia hardly at all, suggesting that
the bacteria may create the environment for intestinaltype gastric carcinogenesis (atrophy and hypochlorhydria)
rather than causing the cancer directly. The risk of developing GC for infected persons is estimated to be between
two and three times higher compared to none infected
ones 4. More recently, the role of individual susceptibility has been stressed and proinflammatory cytokine gene
polymorphism has been demonstrated to interact in the
compound process of gastric carcinogenesis in several
studies 5. In particular, some Authors investigated the
relationship between interleukin-1 gene polymorphism
and GC risk. The conclusions supported the theory in
which host genetic factors affecting the inflammatory and
immune response to H. Pylori infection may determine
a higher risk of GC development, in particular in high
risk area 6. In addition, a variety of studies have indicated that salted, smoked, pickled and preserved foods
(rich in salt, nitrite, and preformed N-nitroso compounds) as well as meat intake are associated with an
increased risk of non-cardia gastric cancer 7. In GC, the
absence of H. Pylori infection is related with specific
clinicopathologic factors impacting GC long term survival. Negative H. Pylori status is associated with cardia
tumor location, advanced pT classification, noncurative
surgery, and a lower 5-year survival rate after R0 resection. Marrelli et al. demonstrate that H. Pylori status is
a significant prognostic factor in which negative H. Pylori
status appears to be an indicator of poor prognosis in
patients with GC 8.
Microsatellite instability and oncogenic mutations
MSI is defined as the presence of replication errors resulting in insertions or deletions of bases within nucleotide
repeats, known as microsatellite regions.
MSI and chromosome instability are two major genomic instability pathways involved in GC pathogenesis; in
particular, MSI is the hallmark of hereditary non-polyposis colorectal cancer (HNPCC) tumors and it also
occurs in about 15% of sporadic carcinomas of the
HNPCC spectrum. In stomach cancer, MSI occurs in
15-30% of cases and it tends to occur preferentially in
intestinal tumors of the antrum of elderly patients with
good prognosis 9,10. Other pathologic features of MSI
gastric tumors are less invasion of the serosa, and involvement of fewer lymph node with lower rate of lymphovascular invasion, relating with less tumor aggression and
lower disease stage. Among GC with MSI phenotype,
recently, Corso et al. described a subset of tumors with
all unstable markers showing a good long term survival.
This data delineate a novel MSI tumor with less biological aggression and favorable prognosis 10.
Germline defects in mismatch repair genes (MMR), such
as hMSH2, hMLH1 and MSH6, have been described in
HNPCC. Tumors with MMR defects show an increased
rate of instability that can lead to the inactivation of
Ann. Ital. Chir., 83, 3, 2012
173
G. Corso, et. al.
specific target genes 11 which play a role in MSI tumorigenesis. Very few cases of sporadic GC show mutations
of MMR genes 12, whilst MSI phenotype is observed in
15-30% of the cases.
MSI gastric carcinomas harbour an increased rate of
mutations in repeat regions, namely in non-coding
sequences and in target genes, as well as in oncogenes,
namely in genes belonging to the mitogen-activated protein kinase (MAPK) cascade and phosphatidylinositol 3kinase (PI3K) pathway. Within the MAPK pathway
KRAS gene is commonly mutated in all types of cancer
but in GC the frequency of mutations in this gene is
low and it varies between 3 to 28% depending on the
series under analyses. Further whenever present KRAS
mutations cluster in MSI GC 13, 14. In MSI GC, as in
other types of cancer, the majority of KRAS somatic
mutations have been detected in hotspots regions of the
gene, namely in codons 12 and 13. Activation of RAS
gene potentiates the MAPK by the engagement of the
cytosolic protein RAF. BRAF mutations occur in about
40% of MSI colorectal cancinomas, in a mutually exclusive manner with KRAS mutations, but in GC activating mutations of this gene were rarely found in most
series 15-19. Within the PI3K pathway, PIK3CA gene
mutations are found in different tumour types and represent an important molecular event in carcinogenesis 20.
Velho et al. previously reported that PIK3CA gene mutations occur in MSI gastric carcinoma with a high/ moderate mutation rate 21.
E-cadherin (CDH1) gene deregulation
CDH1 gene maps to chromosome 16q22.1 and consists
of 16 exons occupying about 100 kb of genomic DNA
and encodes for a 120 kDa protein called E-cadherin
(E-cad). E-cad is a member of transmembrane glycoproteins family expressed on epithelial tissue and responsible for calcium-dependent cell-to-cell adhesion. E-cad
has been demonstrated to be critical for establishing and
maintaining polarized and differentiated epithelia
through intercellular adhesion complexes. Human E-cad
is considered an invasion suppressor and its deregulation
is often found in advanced cases of sporadic GC.
Underexpression of E-cad is also correlated with infiltrative and metastatic ability of the tumor 22; this is due
to the disruption of cadherin-catenins complex, and the
consequently loss of cell adhesion and concomitant
increase in cell motility. E-cad gene is regarded as a classical tumor suppressor gene that occurs early in GC carcinogenesis; it is hence expected to suffer inactivation of
both alleles to be suppressed. As reported, patients with
autosomal dominant inherited tumors have a mutated
allele in the germline while the other (wild-type) allele
is inactivated only in tumor tissue. The impairment of
gene function on the wild-type allele is known as the
‘second inactivating hit’ and it is due to one of the fol-
174
Ann. Ital. Chir., 83, 3, 2012
lowing mechanisms: somatic mutation, loss of heterozygosity (LOH) and promoter hypermethylation.
Somatic mutations of CDH1 are frequently described
in sporadic diffuse GC (DGC). It has been demonstrated in about 50% of DGC but not in intestinal
histotype 23. Berx and colleagues reported that the most
frequently observed changes in DGC are splice site variants that cause skipping in exon 8 or 9 and account
for in-frame deletions. Conversely, missense and truncating mutations are seldom observed 24. Machado and
colleagues searched for CDH1 gene somatic mutation
in 23 GC patients. Among these, somatic mutations
were identified in 9 (39.1%) patients affected by DGC.
The authors concluded that E-cad mutation stands frequently for the second inactivating hit in DGC but
not in intestinal GC 25.
In sporadic GC (diffuse as well as intestinal), LOH is
reported with a wide range of frequency (3-60%). Liu
and colleagues reported a high frequency (38%) of LOH
of CDH1 gene for intestinal and diffuse GCs. The
authors concluded that LOH is one of the major mechanism of E-cad inactivation 26. Differently, Machado and
colleagues found LOH to be responsible of CDH1 gene
impairment in only one out of 9 (11%) sporadic DGC
patients 25.
CDH1 gene promoter hypermethylation is the most frequent event underlying second genetic hit in GC. DNA
is methylated (addition of –CH3 groups) at cytosine
located 5’ to guanosine in the CpG island; this mechanism has an important regulatory effect on gene expression especially when the promoter region of the gene
that controls transcription process is involved. Aberrant
promoter methylation and the associated loss of gene
expression commonly occur in several types of human
cancer. Tamura and colleagues indicated that CDH1 promoter hypermethylation may play a major role in causing the inactivation of E-cad gene in GC, and especially in DGC. At immunohistochemical analysis, hypermethylation of the promoter region was associated with
a reduced E-cad tumor tissue expression 27. Considering
the experience reported by Machado and colleagues,
CDH1 promoter hypermethylation was reported in
56.2% and 28.6% of DGC and intestinal GC, respectively 25. Liu and colleagues reported promoter hypermethylation in 76% of DGC and in 50% of intestinal
GC 26. Graziano and colleagues investigated the relationship between the epigenetic change of CDH1 and
the outcome of 73 patients with surgically resected DGC.
This experience showed CDH1 promoter hypermethylation in 40 cases (54%); a significant association was
found between the tumors with hypermethylation and
the distribution of disease-free and relapsed patients 28.
Grady and colleagues demonstrated that hypermethylation of CDH1 promoter region is the most important
mechanism underlying the second genetic hit in HDGC.
In this study, the authors postulated that promoter
methylation had a reversible nature with a possible attrac-
Gastric cancer carcinogenesis and tumor progression
tive target for the development of new anti-cancer therapies 29.
nevertheless, the study of early hereditary diffuse gastric
cancer lesions in germline E-cadherin (CDH1) mutation
carriers suggests that E-cadherin loss could be an early
or initiating event in tumorigenesis.
Conclusions
The exact mechanisms underlying gastric carcinogenesis
are not yet fully understood, but evidence points to an
association with pathways involved in developmental
processes.
Several factors (infectious, nutritional and genetic) have been
demonstrated to interact in the multifactorial process of gastric carcinogenesis. A strict correlation between H. Pylori and
gastric cancer has been reported and H. Pylori is currently
classified as type I (definite) carcinogen by the International
Agency for Research on Cancer. The risk of developing GC
for infected persons is estimated to be between two and
three times higher compared to none infected ones. More
recently, the role of individual susceptibility has been stressed
and proinflammatory cytokine gene polymorphism has been
demonstrated to interact in the compound process of gastric carcinogenesis in several studies between interleukin-1
gene polymorphism and GC risk. In addition, a variety of
studies have indicated that salted, smoked, pickled and preserved foods (rich in salt, nitrite, and preformed N-nitroso
compounds) as well as meat intake are associated with an
increased risk of non-cardia gastric cancer.
MSI is the hallmark of HNPCC tumors and it also
occurs in about 15% of sporadic carcinomas of the
HNPCC spectrum. Probably, environmental factors may
play a role in generating MMR deficiency leading to
MSI phenotype. Some studies showed an association
between MSI, positive family history of GC and high
consumption of red meat and nitrates, suggesting that
environmental factors, such as nutritional habits may play
a key role in inducing genomic instability and an
increased risk for GC. General environmental exposures,
such as diet, were considered as potential generators of
increased microsatellite alterations in tumors with an
increased tolerance to DNA damage associated with
reduced MMR activity.
The etiology of GC includes also two well-known autosomal dominant hereditary syndromes: the (HNPCC)
caused by mutations or epigenetic silencing in DNA mismatch repair genes, mainly mutations of MLH1 and
MSH2, and the Hereditary Diffuse Gastric Cancer due
to E-cadherin gene (CDH1) mutation.
A role for E-cadherin in tumor development is well
established, with many human carcinomas exhibiting
reduced E-cadherin expression relative to their normal
cellular counterparts. In sporadic diffuse gastric cancers
and lobular breast cancers, E-cadherin inactivation is
associated with somatic point mutations of the E-cadherin gene, as well as loss of heterozygosity, promoter
hypermethylation or overexpression of transcriptional
repressors. In most carcinomas loss of E-cadherin is usually a late event associated with invasion and metastasis;
Riassunto
Il cancro gastrico (GC) rimane una delle cause principali di morte per cancro in tutto il mondo, anche se
negli ultimi decenni è stato osservato un calo nella sua
incidenza e nel tasso di mortalità.
La carcinogenesi gastrica è un fenomeno complesso che
coinvolge molteplici fattori epigenetici e genetici; diversi agenti genetici, ambientali e infettive interagiscono provocando un effetto cumulativo nelle fasi iniziali della carcinogenesi gastrica.
Le classificazioni più comunemente utilizzate di CG sono
quelle dell’Organizzazione Mondiale della Sanità (OMS) e
la classificazione di Laurén che descrive i due principali
tipi istologici, diffuso ed intestinale, che hanno diverse
caratteristiche clinico-patologiche. Il cancro diffuso si verifica più comunemente nei pazienti giovani, può essere multifocale, spesso non è accompagnato da metaplasia intestinale e può essere ereditario; in questa forma l’alterazione
della E-caderina svolge un ruolo fondamentale.
Il tipo intestinale è più frequentemente osservato nei
pazienti anziani ed è associato ad una gastrite atrofica
multifocale. Questa forma è di solito accompagnata da
metaplasia intestinale e porta al cancro attraverso displasia, pertanto la metaplasia intestinale è considerata un
marker morfologico affidabile per il rischio di GC.
La forma intestinale di adenocarcinoma gastrico predomina nelle zone ad alto rischio, la forma diffusa invece è
più comune nelle zone a basso rischio. Classicamente,
l’instabilità genetica e l’ infezione da Helicobater pylori
(H. Pylori) sono spesso identificate nella forma intestinale di GC. La grande maggioranza di GC sono sporadici
e risultato dagli effetti cumulativi dei diversi fattori di
rischio ambientale; il consumo di fumo, l’alcool e le abitudini alimentari sono stati considerati significativi.
L’infezione da H. Pylori ed i poliforfismi dei geni delle
citochine pro-infiammatorie fanno parte di questo complesso meccanismo che conduce allo sviluppo del GC.
Un altro percorso molecolare ben descritto nel GC è
l’instabilità dei microsatelliti (MSI), che si collega con
specifiche caratteristiche clinico-patologiche.
In questa review ci siamo concentrati sul ruolo delle infezioni da H. Pylori, MSI e alterazioni del gene CDH1
(E-caderina).
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